Module for building facades and method of use in construction

ABSTRACT

Module for building façades for any building or civil-engineering project with planar or curved surfaces of two or more walls of reinforced mortar or concrete, which comprises walls; connectors constructed in situ, or prefabricated with drills; connector and wall reinforcements; leaf supports with hollow cylinders or prisms, and a solid support with drills. Use of the building module involves placing the double-Ieaf or solid support; placing reinforcements for each wall alongside each face of the support; inserting the connector reinforcements into the hollow cylinders or prisms, or into drills; folding and overlapping the reinforcement pins; forming connectors and walls, casting concrete or mortar and packing hollow cylinders and prisms, or drills, and on both faces of said supports. Alternative methods involve the use of prefabricated connectors; application in cases without access to one face, against an embankment, and in façade reinforcements.

OBJECT OF THE INVENTION

A general object of the invention is the design of a module to generate surfaces in a given construction capable of application in different areas of the construction sector, in edifices and in engineer works.

A second general object of the invention is a method using the module to generate surfaces in:

-   -   General surfaces' construction procedure in which both faces of         same can be accessed by operators and machinery     -   Construction without access to one of the surface faces, as a         surface attached to an excavation embankment or attached to a         party wall or to a surface with one face towards void.     -   Reinforcement of an existing vertical, horizontal, slanted         surface or with curvature.     -   Construction in situ of bearing walls, separation walls,         pillars, floors, slabs, consoles, roofs, vaults, domes;         construction of all types of previously mentioned surfaces in         engineer works, and furthermore abutments, stacks and bridge         boards, frames and vaults for highway and railway under-passes,         walls and frames to channel rivers and ravines, liquid         containment deposits, walls and crates for port docks, water         reservoir dams.     -   Construction of foundation slabs and contention walls and         previously mentioned structures in the engineer work, as well as         buried or semi-buried water containment deposits, gallery and         tunnel revetments, and bridge abutments.     -   Construction of prefabricated parts in shop to be assembled in         situ as well as engineer works and edifices.

A particular object of the invention is the design of a module to generate surfaces that can be used in different areas of the construction sector, based on polymeric material solid mountings and in alternative materials to polymeric ones such as concrete blocs, ceramic elements' parts, and granular material.

A second particular object of the invention is the design of a module to generate surfaces that can be used in different areas of the construction sector based on polymeric material sheet mountings or an alternative to polymeric materials such as wooden boards, laminated wood, and wooden agglomerates, metallic ones; said sheets separated by prisms or hollow cylinders of polymeric materials; of wood, laminated wood, wooden agglomerates, metallic or carton.

A third particular object of the invention is the design of complementary parts of the module to generate surfaces such as connectors, wall armatures and connector armatures, based on concrete or cement mortar and steel respectively, and in alternative materials to steel as polymeric materials, other metals, glass and carbon fibers.

FIELD OF THE INVENTION

The invention is related to the design of an innovative module to generate surfaces and their parts, that can be used in diverse areas of the construction sector, both in edifices and engineer works, including not only the use of concrete poured into the mold, but also shooting concrete on laminar or solid support shot on mountings and using alternative materials to concrete or cement mortar in some of its parts. Additionally it aims to develop a method to apply said module in the generation of surfaces in the field of building construction and engineer works in different conventional structures.

BACKGROUND OF THE INVENTION

Use of concrete with steel bars goes back to the end of the XIX century to obtain a composite material having the characteristics of concrete as to its resistance to compression and those of steel, most of all regarding its tensile strength.

The structural concrete elements are fabricated preparing an enclosure by means of a mold known as formwork with the shape of the desired structural element. Steel armatures are placed in the inside of said mold in the areas and direction supporting traction when said element is overloaded, filling afterwards the enclosure with poured concrete and consolidating it by means of bar chopping or vibration. Once concrete sets in and hardens the mold is removed in the procedure known as stripping.

The different structural elements can also be prefabricated in shop so that once the concrete hardens they can be transported to the construction site. These prefabricated parts might be lightened boring holes inside them as is the case of hollow slabs. Before pouring of concrete previous tension can be applied to armatures as is the case of pre-stressed concrete parts, or said structural elements may have hollow ducts so that once they are placed in the construction site, cables or steel tendons can be introduced through them to tense them afterwards; an operation known as post-tensing.

However the need of well designed constructive elements built in situ or prefabricated in shop, thus simplifying work in diverse applications in the field of construction and also saving materials and labor with a resulting relevant economic effect, is increasingly evident.

Patent GB 2023215 of Jun. 15, 1979 to Luddington Enterprises Ltd. discloses a constructive two-walled reinforced concrete element, built by projecting bars overlapping with the armature grills of the walls on a two-sheet support, separated by steel bars either horizontal or in a lattice pattern. However, the connection between the two walls is limited by its relatively weak mechanical resistance; it can only be used in surfaces submitted to low stress as in buildings' closures or small bearing walls.

Document U.S. Pat. No. 3,982,368 of Dec. 18, 1974 to American Volkscastel International claims a two-walled shot concrete constructive element wherein the cavity between walls is achieved with a wavy carton support sheet. The claimed element has two connectors between walls made up of steel bars overlapping in the armatures of walls. There is another alternative wherein walls are braced by means of concrete partitions provided at a certain distance. The alternative in which bracing between walls is achieved by means of concrete partitions is the one presenting more rigidity, mostly in the direction of partitions while it is scarcely rigid if perpendicularly. The U.S. Pat. No. 3,982,368 invention is designed for prefabricated panels that are assembled in the metallic frames through bolts to the forging borders. It is designed to build only flat surfaces submitted to low stress as in buildings' closures.

Document DE 19520082 of Jun. 1, 19955 to Bitttscheidt, Norbert, Datteln, discloses a double-walled prefabricated concrete double-walled lost formwork to build vertical packed concrete walls a posteriori. Formwork is not recuperated as in traditional procedures. The proposed system aims to build solid concrete walls instead of hollow ones. It is useful only in vertical surfaces, needing a significant amount of concrete.

Thus the need of an innovative solution having adequate rigidity in all directions, able to be used in the construction of any surface, even those requiring high resistance requirements as to stress. It should equally be versatile enough so it can be used in the construction of prefabricated panels as Perrin's, but also to build in situ any surface or edifice; building any surface even with curvature as in vaults, domes or any warped surface, allowing for variable separation between walls allowing adaptation in each spot according to required stress level of said spot.

DESCRIPTION OF THE INVENTION

Features of the Present Surface Generating Module

The surface generating module of the invention used in a given construction has some features previously mentioned providing at the same time state of the art inventive, novel features. By means of repetition, the surface generating module of the invention generates the full structure.

In the first place, contrary to normally used art in structure design wherein said structures are made up of linear elements, the ones built according to the invention are made up of elements of a mainly superficial character. Superficial dimensions of surfaces built using the surface generating module of the invention are clearly superior as to their thickness.

At the same time the concept of formwork to configure an enclosure in which concrete is poured disappears, using in this case a mounting to shoot concrete or mortar on both faces of same. The mounting is not necessarily removed but left inlayed in the surface. Thus it results in a very light element for surface building wherein concrete or mortar is placed only in areas of compression stress originated by structure loading and to cover steel bars supporting tensile stresses.

The surface generating module of the invention enables construction of all types of structural elements and shapes, either superficial ones as slabs, floor slabs, floors, brackets, vaults, water deposits, contention reinforced walls, bearing walls, closures, partitions, bridge boards, as well as linear structural elements as pillars, bridge piers, beams, girders; also volumetric structural forms as gravity dams o vault dams for water reservoirs.

The present surface generation module comprises at least two concrete or mortar walls, although they can also be made of reinforced cement mortar, coupled by connectors at a certain distance, which are generally of the same material, or of polymeric material; metallic, wooden; carbon fibers reinforced resin, glass fibers reinforced resin; or any other type of material with sufficient mechanical strength according to requirements of the constructive object to be built.

As main innovative feature of the surfaces' generating module of the invention is the fact that it increases the inertia momentum of a surface regarding its medium plane, separating walls inwardly without increasing construction material requirements, as is the case of formwork concrete elements, wherein to increase momentum of inertia, thickness of surface has to be increased generating more material consumption, labor and time. Thus, the present element provides very resistant structures with a much lower use of resources. Structures built applying this invention are much more resistant to seismic movement strains. All of this results in an important saving of resources, rendering a significant applicability and an important economic effect.

Building Procedure

The following method can be applied to build a surface for any construction using the present surface generating module when using a solid mounting.

-   -   a) Preparation of support as to dimensions and location of         surface to be built. The support should be made up of light         material, easily moldable, cut and drilled.     -   b) Drills are bored in said support with the dimensions and         shapes of connectors used to join the walls. Drill section         coincides with that of the future connector and its depth with         connector's length.     -   c) Armatures are introduced through drills of future connectors.         Armatures carry pins to overlap with wall armatures.     -   d) Armatures are attached and fixed to each face of support of         each future wall.     -   e) Pins of connectors' armatures are folded and overlapped or         welded with armatures of walls.     -   f) Once all armatures are placed and overlapped on the support         and said support is correctly placed according to the shape of         the surface, concrete or mortar is shot beginning by filling         drills and thus forming connectors, then     -   g) Concrete or mortar is shot against one of the support faces         covering armature and providing required thickness, thus forming         one of the walls.     -   h) Concrete or mortar is shot on the other face of the support         covering the corresponding armature, forming the second wall.

If the surface generating module is three-walled, operations previously described are repeated except folding of connector armature's pins in the face wherein third wall is to be built. Next a second support is attached to the wall already built with drills facing salient pins of connectors so that pins, once the second support is placed, protrude through its drills. Next armatures of second wall are placed. Protruding armatures of connectors are folded and overlapped with those of the third wall and concrete or mortar is shot beginning by filling drills of second support, and next on seen face of second support, covering armatures and thus forming the third wall. If said generating module of the invention has more walls the operation is repeated until completion of all walls.

Alternatively, connectors can be prefabricated in shop instead of in situ as previously described. In this case, these are cylinders or prisms of reinforced concrete or mortar with two or four parallel drills close to both bases of said elements. Once in the construction site they are introduced in the support drills. Wall armatures are placed at both faces of support and tied bars overlapping armatures of future walls are introduced through connectors' drills. Tied bars introduced in connectors should be impregnated with resin so that they adhere to said concrete or mortar of connector's drill along contact surface. Once all prefabricated connectors and armatures of both walls have been placed, concrete or mortar is shot on one face of the support, thus forming the first wall and afterwards concrete or mortar is shot on the other face of the support thus forming the second wall.

Instead of solid as previously described, support can also be made up of two sheets of selected material, separated at a certain distance and hollow inside. Both sheets have facing drills and cylinders or hollow prisms going from a sheet drill to the opposite one. Once double-sheet support is made with specified dimensions of the surface to be built, armatures of future connectors are introduced through the cylinders or hollow prisms. Future walls' armatures are placed in each external face of the support, folding armature pins of connectors, overlapping them with armatures of both walls, casting concrete or mortar beginning by filling cylinders or prisms and next casting concrete or mortar in turns on one face of the support and then on the other.

In the void between walls diverse conduits as water pipes or electrical tubing can be installed. Also if this space is vertical the surface can be filled with soil and used to plant flowers. If horizontal, the void between walls might be filled with gravel to increase load which could be appropriate in floor slabs or other types of structural elements. Separation between walls of the present generating module of the invention may be variable. Said walls can present any curvature. Before hardening of concrete or mortar begins, if necessary, it can be trimmed, trowelled or given corresponding superficial finish to each wall.

It is also possible to make up a surface according to the invention when there is no access to one of the surfaces to be built, by preparing a first support without drill with the shape of the future surface; this first support can even be the embankment of an excavation and if so, a first wall armature and connectors' armatures are placed in this support. Next concrete or mortar is shot thus forming the first wall; afterwards a second support is attached to this first wall, being said support solid or of double-sheet. Drills of this second support are arranged so that when attaching same to the already built wall, connectors' armatures are introduced through the drills protruding from them. Next armatures of second wall are placed, folding and overlapping pins of connectors' armatures of second wall casting concrete or mortar, filling drills and covering armatures of second wall, thus finishing same.

When the generating module of the second wall of concrete or mortar of the invention is to be used as reinforcement of an existing structure, instead of demolishing said wall and building a new one whether it is damaged or deteriorated, or a change of use is desired to increase for example, its loading capacity; the reinforcement method is as follows:

-   -   a) First the structure is tubbed so that work can be carried out         safely since the edification proper acts as support for casting         of concrete or mortar.     -   b) According to reinforcement design, a series of drills are         bored in all the surfaces to be reinforced.     -   c) Connectors' armatures are introduced through these drills     -   d) Next, armatures corresponding to each wall of designed         armature are fixed in each face of surface to be reinforced.     -   e) Connectors' armature pins are folded in each face of the         surface, overlapping them with corresponding armatures placed in         each wall.     -   f) Concrete or mortar is shot beginning by filling drills thus         forming connectors, next concrete or mortar is shot on one face         of the surface, covering existing armature thus forming first         wall     -   g) Next, concrete or mortar is shot on second wall of the         surface thus finishing second wall.

Alternatively, connectors can be prefabricated in situ for this reinforcement application. In this case, the work method is similar, but introduction of connectors' armatures and pins folding is substituted by introduction of prefabricated connectors and tied bars impregnated with adherent resin through drills having prefabricated connectors in both bases, overlapping these tied bars with armatures of respective wall. Finally concrete or mortar is shot on both faces.

Thus former construction is embedded in the double wall formed by said reinforcement.

Applications of the Generating Module of the Invention.

Industrial application of the surface generating module for double or multiple concrete or mortar walls focuses mostly on building construction and in engineer works. All types of structural elements, surfaces and architectural forms used in constructions and engineer works can be built with same.

The surface generating module of the invention enables construction of: foundation slabs, basement walls, load walls, closure walls, separating walls of spaces, pillars, beams, girders, drop forgings, and all types of covers, brackets, vaults, domes, etc.

Besides the ones previously mentioned, applications of the surface generating module of the invention in engineer works include: construction of water storage deposits, soil containment walls, enclosures for maritime port barriers, abutments, stacks and aqueduct and viaduct bridge boards, gravity dams o vault dams as water reservoirs, revetment of tunnels and galleries and in general, forming of any structure or part of same.

With the present generating module of the invention any type of conventional elements can be built in the areas of in shop prefabricated reinforced concrete parts to be carried and placed in engineer works, including self carrying panels, floors, pillars and stacks, girders, slabs, etc. These parts can have any required form or dimension.

The present element is quite useful as a reinforcement system of damaged structures whether in buildings or in different engineer works.

DESCRIPTION OF THE DRAWINGS

FIG. 1 presents the generating module of concrete or mortar double wall of the invention

FIG. 2 presents a perspective of a fragment of the surface (support omitted) built using the generating module of the invention

FIG. 3 presents the double-sheet support with nine prisms or hollow cylinders corresponding to the fragment of the surface illustrated in FIG. 2.

FIG. 4 presents an alternative type of support, a solid support with nine drills in the support corresponding to the fragment of the surface in FIG. 2.

FIG. 5 shows a schematic plant view of the fragment of the surface of FIG. 2.

FIG. 6 illustrates two details of sections represented in FIG. 5 wherein a solid support is also represented.

FIG. 7 illustrates details of FIG. 6 in case of double-sheet support

FIG. 8 illustrates a perspective of all armatures of the fragment of the surface of FIG. 2, including armatures of both walls and those of the nine connectors.

FIG. 9 represents a plant view of armatures of FIG. 8.

FIG. 10 illustrates three connectors of sections of FIG. 5, with their armatures and both walls with their corresponding armatures.

FIG. 11 represents bracing of the two walls by means of connectors prefabricated of concrete or reinforced mortar according to the invention.

FIG. 12 illustrates the typical reinforcement method of an existing surface.

PREFERRED EMBODIMENTS

Generating Module of the Invention

Embodiment No. 1. Components of the Generating Module

FIG. 1 presents the concrete or mortar two-walled surface generating module of the invention, illustrating orientation of the element capable of assuming any possible direction, illustrating as well walls 1 and connector 2 joining said walls 1, and armatures 7 of connector and corresponding armatures 8 of said walls 1; also indicating concrete or mortar 9 as the material used in this generating module. In vertical or slanted surfaces casting is used to fix in place concrete or mortar 9. In horizontal or less inclined surfaces fixing in place can also be accomplished by pouring.

FIG. 2 provides additional information showing in perspective a facade fragment built with the generating module of the invention. The figure only illustrates concrete or mortar elements 9, omitting the support, either a double-sheet one 4 or solid (see FIGS. 3 and 4). The two walls 1 and three connectors 2 are visible, while remaining six connectors 2 are hidden by the upper wall.

Embodiment No. 2. Types of Support s

FIG. 3 presents the double-sheet support 4 corresponding to surface fragment shown in FIG. 2, comprising two sheets 4, separated by nine prisms or hollow cylinders 3; illustrating as well the nine upper bases of prisms or hollow cylinders 3, inner part of the six hollow prisms 3 and three hollow cylinders is visible, sticking out outer part of three hollow cylinders 3.

FIG. 4 presents another type of support corresponding to surface fragment represented in FIG. 2, in this case a solid support 5, showing the nine drills 6 bored in solid support 5 wherein six of them are prism shaped while the remaining three are cylindrical.

Embodiment No. 3. Connectors

For a better understanding of the invention, FIG. 5 presents a schematic plant view of surface fragment of FIG. 2. It presents two sections, section AB not cutting any connector 2 and section CD cutting three connectors 2. Section AB rifling shows concrete or mortar 9 area cut by the section; only two walls 1 of the surface fragment were cut in this case. Rifling of section CD shows this section cuts concrete or mortar of the two walls 1 and three connectors 2.

FIG. 6 shows more detailed information of the two-walled generating module of the invention, presenting two details of section AB and CD of FIG. 5 when using a solid support 5. The first detail corresponding to section AB of FIG. 5 illustrates how said section AB does not cut through concrete or mortar 9 of connector 2 but instead cuts completely through solid support 5 also affecting walls 1. The first detail corresponding to section CD shows how said section CD cuts concrete or mortar 9 of connector 2.

For the same detailed information of the double-walled generating module 1, FIG. 7 illustrates two details of sections AB and CD of FIG. 5 when using a double-sheet support 4 of the invention. First detail corresponds to section AB that does not cut connector 2, showing double-sheet 4. Second detail corresponds to section CD that cuts connector 2, showing double-sheet 4 and hollow prism 3.

Embodiment No. 4. Armatures

FIG. 8 illustrates a perspective of all armatures of surface fragment of FIG. 2, showing both armatures 8 of all walls and also armatures 7 of the nine connectors 2.

An additional view of armatures shows in FIG. 9 a plant view of FIG. 8 representing armatures 8 of the upper wall 1 and armatures 7 of the nine connectors 2.

FIG. 10 represents the three connectors 2 of sections of FIG. 5. Lower detail shows armatures 7 of connectors 2 and armatures 8 of walls 1. Upper drawing of this figure shows disposition of armatures 7 and 8 respectively providing a strong coupling between the two walls 1 by means of said connectors 2. The figure also shows concrete or mortar 9 materials of walls 1.

Embodiment No. 5. Reinforced Concrete or Mortar Prefabricated Connectors

Coupling of walls 1 of generating module by means of reinforced concrete or mortar prefabricated connectors 10 is shown in FIG. 11. Prefabricated connector 10, that might be cylindrical or prism shaped, is represented—in this case—in the right hand side detail of said figure, having close to each of its two bases at least two drills 14 parallel to them. Once the double-sheet 4 or solid support 5 has been placed, each prefabricated connector 10 is introduced through hollow cylinders or prisms 3 if said support is of double-sheet 4 or through drills 6 if it is solid 5. Next armatures 8 of the two walls 1 are fixed in place introducing tied bars 11 through drills 14 of both bases of the prefabricated connector 10, impregnating previously with resin 12 each bound bar 11 in the contact area between said bound bar 11 and corresponding drill 14 of prefabricated connector 10; said resin 12 guarantees adherence between tied bars 11 and prefabricated connector 10. Concrete or mortar 9 is then cast on both faces of the support, either two-walled 4 or solid 5, thus forming said generating module of the invention.

Embodiment No. 6. Reinforcement of Existing Surface

Method of reinforcement of existing surface 13 with the generating module of the invention is illustrated in FIG. 12. Surface 13 can have a vertical, horizontal or slanted position, also with curvature. If necessary, it is first tubbed so that following operations are safe. Next drills 6 a are bored in surface 13 according to reinforcement design, then armatures 7 of connectors 2 are introduced through said drills 6 a. Armatures 8 of the two future walls 1 of reinforcement are attached to each face of surface 13. Next pins of armatures 7 of connectors 2 are folded overlapping them with armatures 8 of walls 1. Finally concrete or mortar 9 is cast beginning by filling drills 6 a thus forming connectors 2, casting concrete or mortar 9 continues on one face of surface 13 and then on the other, thus finishing reinforcement by means of the generating module of the invention. Once concrete or mortar 9 is cured and sufficiently aged to provide necessary resistance tubbing is removed from the structure.

Generating Module Usage Method

Embodiment No. 7. General Method

General building method is as follows: placing support, either of double-sheet 4 or solid 5 with shape and dimensions of the whole surface of the construction to be built or part of it. Armatures 8 of each wall are attached to each face of the mounting, armatures of connectors 7 are introduced through prisms or hollow cylinders 3 of mounting if same is of double-sheet 4 or through drills 6 if solid; pins of longitudinal armatures of connectors are folded and overlapped to armatures 8 corresponding to each wall 1. Concrete or mortar 9 is shot packing prisms or hollow cylinders 3 if mounting is double-sheet 4 or drills 6 if it is solid 5, thus forming connectors 2. The casting of concrete or mortar 9 on one face of the mounting and then on the other continues until achieving required thickness in each wall 1. If generating module of the invention to be used is three-walled 1 the same method is followed as previously explained except folding pins of armatures 7 of connectors 2 in the face of mounting 4 or 5 where third wall is to be formed. Once concrete or mortar 9 of second wall 1 is shot then second mounting is attached to same so that unfolded pins of connectors pass through hollow prisms or cylinders 3 of second mounting if this is of double-sheet 4 or through drills 6 if it is solid 5, placing then armatures 8 of third wall 1. Pins of connectors 2 are folded overlapping them with armatures 8 of third wall 1 filling prisms 9 or hollow cylinders 3 of second mounting with concrete or mortar if said mounting is double-sheet 4 or drills 6 of second mounting 5 if solid, then shooting concrete or mortar 9 on seen face of said second mounting 4 or 5, completing third wall 1. If generating module of surfaces has more walls the method is repeated until completion of all of them. Before concrete or mortar sets in, it can be trimmed or trowelled if certain smoothness is needed in the seen face of any wall 1.

Embodiment No. 8. Method without Access to One of the Surface Faces

Construction method if there is no access to one of the faces of the surface is as follows: a common mounting, not of the invention, is placed with no drills, with shape and dimensions of the surface to be built. Armatures of first wall 8 and armatures of connectors 7 are placed casting concrete or mortar 9 forming first wall 1; a second mounting, of double-sheet 4 or solid 5 is attached with prisms or hollow cylinders 3 in the first case or with drills 6 in the second case so that longitudinal armatures 7 of connectors 2 pass through said hollow prisms or cylinders or drills; armatures of second wall are attached to this second mounting, folding and overlapping pins of longitudinal armatures of connectors 7 to armatures of second wall 8, filling with concrete or mortar 9 hollow prisms or cylinders 3 in the first case or drills 6 in the second case thus forming connectors 2, casting of concrete or mortar 9 continues on seen face of mounting thus forming second wall 1.

Embodiment No. 9. Construction Method of Surface Attached to an Excavation Embankment or to an Existing Surface

Construction method when a surface is attached to an excavation embankment or to an existing surface is as follows: Armatures of first wall 8 and armatures of connectors 7 are attached to excavation embankment or existing surface. Concrete or mortar is cast on embankment or on existing surface covering armatures of wall 8, thus completing first wall 1. A double-sheet 4 or solid 5 mounting is attached so that longitudinal armatures of connectors 7 pass through hollow prisms or cylinders 3 if the mounting is of double-sheet 4 or through drills 6 if it is solid 5, armatures of second wall 2 are placed, folding and overlapping longitudinal armatures of connectors 7 with those of second wall 8. Concrete or mortar 9 is shot filling hollow prisms or cylinders 3 or drills 6, depending on type of mounting used, thus forming connectors 2, shooting of concrete or mortar 9 continues on seen face of mounting thus completing second wall 1.

Embodiment No. 10. Method with Prefabricated Connectors

In this case the method to build a surface is as follows: Mounting of double-sheet 4 or solid 5 is placed with shape and dimensions of all or part of the edification surface to be built. Armatures of each wall 8 are attached to each face of mounting, introducing prefabricated connectors 10 through hollow prisms or cylinders 3 if the mounting is of double-sheet 4 or through drills 6 if solid 5; tied bars 11 impregnated with resin 12 in their central area are introduced through drills 14 having prefabricated connectors in both bases. If walls 1 needed a second armature grill 8 said second grills 8 are placed in each face of mounting. Concrete or mortar 9 is shot on both faces of mounting, of double-sheet 4 or solid 5 until completion of thickness required for each wall 1.

Embodiment No. 11. Method to Reinforce a Surface

Method to reinforce an existing surface 13, either vertical, horizontal, slanted or with curvature is as follows: if necessary it is tubbed in the first place so that following operations are sufficiently safe. Drills 6 a are bored in said surface 13 according to reinforcement design, armatures of connectors 7 are introduced through said drills 6 a; armatures of the two walls 8 are attached to each face of surface 13, folding pins of armatures of connectors 7 overlapping them with those of walls 8. Concrete or mortar 9 is shot beginning by filling drills 6 a thus forming connectors 2, casting concrete or mortar 9 continues on one face of said surface 13 and then on the other face thus finishing both walls 1. Once concrete or mortar 9 is cured and sufficiently aged to achieve necessary resistance tubbing of the structure is removed.

Embodiment No. 12. Alternative Reinforcement Method Using Prefabricated Connectors

Method to reinforce an existing surface 13 vertical, horizontal or slanted and with curvature is as follows: if necessary it is tubbed in the first place so that following operations are sufficiently safe. Drills 6 a are bored in said surface 13 according to reinforcement design; armatures of walls 8 are attached to each face of said surface 13 and prefabricated connectors 10 are introduced through said drills 6 a; tied bars 11 impregnated with resin 12 in their central area are introduced through drills 14 having prefabricated connectors in both bases, placing if the case, second armature grills 8 of walls 1. Concrete or mortar 9 is cast on both faces of surface to be reinforced 13 until completion of desired thickness of each wall 1. Once concrete or mortar 9 is cured and sufficiently aged to achieve necessary resistance tubbing of the structure is removed.

Embodiment No. 13. Other Prefabricated Elements—Prefabricated Panels and Floating Crates for Port Docks

Prefabricated panels and construction of floating crates are among other applications of the surface generating method of the invention.

Prefabricated panels are prepared in shop as follows: joining of panels 15 in situ is carried out through assembly parts 16 and according to FIG. 13, said assembly parts 16 are introduced between panels thus rigidly joining said panels 15 after screwing said assembly parts 16. Width of said assembly parts 16 is somewhat smaller than desired separation between walls of panel 15.

Construction of floating crates for port docks is as follows: floating crates have a sill 17 according to FIG. 14 wherein surrounding walls 18 and separation walls 19 are embedded so that both said walls 18 and 19 are embedded among them. The sill can be concrete double-walled or solid of same material. All said walls 18 and 19 are double-walled of shot concrete or mortar.

SUMMARY

Thus the present invention provides inventive, novel features as to state of the art. The invention develops the present generating module having rigidity in all directions enabling its use in the construction of any surface no matter the stress it may be subject to. The generating module of the invention is much more versatile than any preceding one as to state of the art since it can be used to make prefabricated panels as Perrin's but also can be directly used in construction works to build any of their parts. Surfaces might have curvatures as is the case of vaults, cupules or any other paddled surface, wherein separation between walls as well as their thickness can be variable allowing adaptation in any spot to required stress level of same. A low caloric conductivity material may be selected to construct the mounting, thus bestowing heat isolation features on the surface constructed according to the invention. Furthermore, structures built applying this invention are much more resistant to strains provoked by seismic movement than conventional ones. 

1-18. (canceled)
 19. A multipurpose module to generate surfaces of any type of structural shape of double or multiple walls (1) of reinforced mortar or concrete (9) inwardly braced through connectors (2 or 10), with armatures (7); provided said module of solid casting mounting (5) with drills (6) and prisms or hollow cylinders (3), sheets (4) characterized by comprising: double grill armatures (8) inwardly separated in each wall (1); connectors (2) of mortar or concrete (9) having longitudinal and transversal armatures (8) or enclosures built in situ; prefabricated connectors (10) of reinforced mortar or concrete (9) of rectangular or circular section, with drills close to each one of their bases (14) to introduce through them tied bars (11) to wall armatures (8); hollow connectors (10) manufactured of tubular type metallic material with circumferential or rectangular section; solid connectors (10) wooden or of polymeric material; solid casting mountings (5) with drills (6) to introduce prefabricated connectors (10) or armatures (7) of connectors in situ (2) and its further packing with mortar or concrete (9); and double metallic sheet casting mounting (4).
 20. The multipurpose module to generate surfaces according to claim 19, wherein said armatures (7) of connectors (2) and said armatures (8) of walls are made of galvanized steel, high strength polymeric fibers' braided cords, vegetable fibers of string type braided cords or carbon fiber cords.
 21. The multipurpose module to generate surfaces according to claim 19 characterized in that said prefabricated connectors (10) manufactured of polymeric material are made up of circular or rectangular section carbon fiber o glass fiber reinforced resin.
 22. The multipurpose module to generate surfaces according to claim 19 wherein said solid mounting (5) comprises: said drills (6) to introduce said armatures (7) of connectors (2); said prefabricated connectors (10); said armatures (8) of each wall placed in both faces of solid mounting (5); and folded pins of said armatures (7) of said connectors (2) or tied bars (11) impregnated with resin(12) in their central area and introduced in prefabricated connectors (10); mortar or concrete (9) shot to fill said drills (6) and casing of said armatures (8) of walls (1) and armature pins (7) or of said tied bars (11).
 23. The multipurpose module to generate surfaces according to claim 19, wherein said mounting is of double metallic sheet (4) and comprises: double metallic sheet casting mountings (4) constituting by themselves the wall armatures (1) of reinforced mortar; prisms or hollow cylinders (3) of same metal welded to both sheets (4) themselves constituting the connectors; reinforced mortar or concrete (9) shot on both faces of the mounting totally covering each metallic sheet (4) on its outer face with appropriate thickness of said reinforced mortar or concrete (9).
 24. The method using a multipurpose module to generate surfaces of any sort of structural shape of double or multiple reinforced mortar or concrete (9) walls inwardly braced through connectors in situ or prefabricated (2 to 10) with armatures (7), the method is carried out: by means of solid mountings (5) with drills (6); in structural configurations without access to one of the faces of surface; in surfaces attached to an excavation embankment or existing surface; by means of double metallic sheet mountings (4) with its prisms or metallic hollow cylinders (3) welded; in generation of surfaces with curvatures or single tubbed planes; in surfaces wherein armature of one of the walls provides shaping; surfaces built with prefabricated connectors; as armature of existing surfaces (13) vertical, horizontal, slanted or with curvature; to reinforce existing surfaces (13) by means of prefabricated connectors (10) of vertical, horizontal, slanted or with curvature types
 25. The method using multipurpose module to generate surfaces of claim 24 by means of solid mountings (5) with drills (6) comprising the following steps: placing the solid mounting (5) with drills (6) with the shape and dimensions of the whole surface to be built; attaching the armatures of each wall (8) to each face of said solid mounting (5); introducing the armatures (7) of connectors (2) through drills (6) of said solid mounting (5); folding and overlap longitudinal armature pins (7) of connectors (2) to corresponding armatures (8) of each wall (1); optionally, placing a second armatures' grill (8) separated from said first armatures (8) from said first wall (1); forming connectors (2) casting mortar or concrete (9) and packing drills (6) of solid mounting (5); shooting mortar or concrete (9) on one face of said solid mountings (5) and then on the other face until required thickness for each wall (1) is obtained; trimming or troweling before mortar or concrete sets in (9) if a certain smoothness is needed in the face of any seen wall (1); and If surface is to have three walls previous steps should be followed except d) in which longitudinal armature pins (7) of connectors are not folded. Once step g) is finished wherein the second wall (1) has been built, a second solid mounting (5) is placed such that pins of said armatures (7) of connectors pass through drills of second solid mounting (5). Next, armatures (8) of third wall are attached to seen face of second solid mounting (5) of third wall and steps d, e, f, g and h are repeated for third wall.
 26. The method using multipurpose module to generate surfaces of claim 24 in structural forms without access to one of the faces of the facade comprising the following steps: placing a first mounting without drill or hole with the shape and dimensions of surface to be built; placing the armatures (8) of first wall (1) and armatures (7) of connectors (2); optionally, placing a second armatures' pin (8) separated from said first armatures (8) of said first wall (1); shooting concrete or mortar (9) to build said first wall (1); attaching a second solid mounting (5) with drills (6) so that longitudinal armatures (7) of connectors (2) pass through drills (6); attaching to said second solid mounting (7) armatures (8) of second wall (1) folding and overlap pins of longitudinal armatures (7) of connectors (2) to armatures (8) of said second wall (1); optionally, placing a second armatures' grill (8) separated from said first armatures (8) of said first wall (1); forming connectors (2) filling with concrete or mortar (9) casting or pouring through drills (6) of said solid mounting (5); and shooting concrete or mortar (9) on seen face of said solid mounting (5) covering armatures (8) until said second wall (8) is totally formed.
 27. The method using multipurpose module to generate surfaces of claim 24 attached to an excavation embankment or existing surface comprising the following steps: attaching to excavation embankment or existing surface armatures (8) of first wall (1) and armatures (7) of connectors (2); optionally, placing a second armatures' grill (8) separated from said first armatures (8) of said first wall (1); shooting concrete or mortar (9) on embankment or existing facade covering said armatures (8) till said wall (1) is completed; attaching a solid mounting (5) so that longitudinal armatures (7) of connectors (2) pass through drills (6) of said solid mounting (5); placing said armatures (8) of second wall (1); folding and overlapping pins of said longitudinal armatures (7) of connectors (2) with said armatures (8) of said second wall (1); optionally, placing a second armatures' grill (8) separated from said first armatures (8) of said first wall (1); shooting concrete or mortar (9) filling said drills (6) of said solid mounting (5) until said connectors (2) are totally built; and continuing casting said concrete or cement (9) on seen face of said solid mounting (5) finishing said second wall (1).
 28. The method using multipurpose module to generate surfaces of claim 24 by means of double metallic sheet mounting (4) with its prisms or metallic hollow cylinders (3) welded to both sheets by its bases for every type of structural forms comprising the following steps: placing double metallic sheet mounting (4) with its prisms or metallic hollow cylinders (3) welded to said sheets (4) with shape and dimensions of the whole facade to be built; forming connectors (2) casting concrete or mortar (9) and packing prisms or hollow cylinders (3); or alternatively leaving prisms or metallic hollow cylinders empty (3), the connectors made up of said prisms or metallic hollow cylinders (3); shooting concrete or mortar (9) on one face of said double metallic sheet mounting; and trimming or troweling before concrete or mortar (9) sets in if a certain smoothness is needed in the seen face of any wall (1).
 29. The method using multipurpose module to generate surfaces of claim 24 with curvature or easily tubbing planes comprising the following steps: preparing a flat or with curvature tubing with the shape of the surface to be built; placing the armatures (8) of the first wall and the armatures (7) of connectors on tubing surface heightened with respect to surface at a distance corresponding to concrete covering of armatures (8) by means of conventional dividers; optionally, placing second armatures' grill (8) separated from said first armatures (8) of said first wall (1); shooting or pouring the concrete or mortar (9) watching fresh mass passes under armatures (8) and (7), thus first wall (1) is formed; next solid mounting (5) of second wall (19) with its drills (6) is placed so that armatures (7) pass through said drills (6) of each connector with emerging pins of longitudinal bars (7); placing armatures (8) of second wall, armatures' pins of connectors (7) are folded overlapping armatures (8) of second wall; optionally, placing a second grill of armatures (8) separated from said first armatures (8) of said first wall (1); and shooting or pouring the concrete or mortar (9) to fill the first drills (6) of solid mounting and proceeding on all the surface of solid mounting (5) until said second wall (1) is finished.
 30. The method using multipurpose module to generate surfaces of claim 24 wherein facade shape is determined by means of armatures of one of the walls comprising the following steps: forming armatures' grill (8) of first wall (1) with the shape of surface, either flat or with curvature, with armatures (7) of connectors anchored to said grill; placing a second armatures' grill (8) separated from said first armatures (8) of said first wall (1); fixing a sheet (4) on the face opposing that of connectors' armatures (7); shooting the concrete or mortar (9) covering grill (8) and pins of armatures (7) of connectors thus first wall is formed (1); fixing a solid mounting (5) with its drills (6) so that armatures (7) of connectors pass through them and overlap mounting (5); placing the armatures (8) of second wall and armatures' pins (7) of connectors folded overlapping them with those of second wall (1); optionally, placing a second armatures' grill (8) separated from said first armatures (8) of said first wall (1); and shooting the concrete or mortar (9) filling first drills (6) and covering afterwards armatures (8) of said second wall (1).
 31. The method using multipurpose module to generate surfaces of claim 24 carried out by means of prefabricated connectors comprising the following steps: placing a solid mounting (5) with said drills (6) with shape and dimensions of surface to be built; attaching armatures (8) of each wall (1) to each face of said solid mounting (5); introducing prefabricated connectors (10) through drills (6) of said solid mounting (5); introducing tied bars (11) impregnated in their central area with resin (12) through drills (14) having prefabricated connectors (10) in both said bases; optionally, placing both second armatures' grills (8) of said walls (1) in each face of solid mounting (5) and separated of the first ones; and shooting concrete or mortar (9) on each face of said solid mounting (5) until completing specified thickness for each wall (1).
 32. The method using multipurpose module to generate surfaces of claim 24 as reinforcement of existing surfaces (13) of vertical, horizontal, slanted types or with curvature characterized by comprising the following steps: placing tubing and fixing to the surface to be reinforced (13) so that following operations are sufficiently safe; practice drills (6 a) in surface to be reinforced (13) according to reinforcement design. Introduce through said drills (6 a) of said surface to be reinforced (13) armatures (7) of connectors (2); attaching to each face of said surface (13) armatures (7) of said connectors (2) overlapping them with armatures (8) of walls (1); folding pins of said armatures (7) of said connectors (2) overlapping them with armatures (8) of walls (1); If necessary, place second armatures' grill (8) separated from said first armatures (8) of said first wall (1); shooting concrete or mortar (9) filling first said drills (6 a) thus forming said connectors (2) of said surface to be reinforced (13); finishing both walls (1) casting concrete or mortar (9) on one face of said surface (13) and next on the other; and removing tubing from structure once concrete or mortar (9) is cured and sufficiently aged to provide necessary resistance.
 33. The method using multipurpose module to generate surfaces of claim 24 as reinforcement by means of prefabricated connectors of existing surface (13) of vertical, horizontal, or slanted types or with curvature comprising the following steps: placing tube and attach to said surface to be reinforced (13) so that the following operations are sufficiently safe; placing drills (6 a) in surface to be reinforced (13) according to reinforcement design; attaching to each face of said surface (13) armatures (8) of the two walls (1); introducing through said drills (6 a) prefabricated connectors (10); introducing tied bars (11) impregnated with resin (12) in their central area through drills (14) of said prefabricated connectors (10) located in both bases; optionally, placing a second armatures' grill (8) separated from said first armatures (8) of said first wall (1); shooting concrete or mortar (9) on both faces of said surface to be reinforced (13) until completing needed thickness of each wall (1); and removing tubing of structure once concrete or mortar (9) is cured and sufficiently aged to provide necessary resistance.
 34. The method using multipurpose module to generate surfaces of claim 24 to build prefabricated panels and floating crates for docks characterized in that: said panels 15 are joined through assembly parts 16 introduced between panels, rigidly joining said panels after screwing said assembled parts 16; and said floating crates comprise a sill 17 in which surrounding walls 18 and separation walls 18 are embedded, thus embedding both types of walls 17 and 18 among them. 